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Latest revision as of 19:29, 18 September 2015
Partnership |
Partner team: Hong_Kong-CUHK
Project: Magneto-bacter vinelandii Magnetosome-forming Azotobacter vinelandii with Downstream Applications |
Background
Task
Calculation
Software - SimBiology
Once the model is constructed (i.e. the mathematic relationships between molecules are set up, parameters such as association constant, molarity of reagent, etc. are provided), we can simulate the reaction or even scan through one or more variables. The “scan” function enables us to simulate the dynamics of the system when some parameters, such as the initial concentration of the reagent, are at different values.
Assumptions
2). Each magnetosome has the same number of GFP-specific nanobodies adsorbed on its surface.
3). A magnetosome does not interact directly with GFP molecules nor interfere with the reactions between GFP-specific nanobodies and GFPs.
4). The GFP-specific nanobodies on the surface of a magnetosome have the same association and dissociation rate constant to GFP when compared with the GFP-specific nanobody alone.
5). The binding of GFP with GFP-specific nanobody is in a one-to-one ratio.
6). The reaction follows the law of mass action, which means the reaction rate is proportional to the concentration of the reagents.
ModelFigure 1 shows the model constructed in SimBiology. The blue rounded rectangles represent the reagents, including antigens (GFP), GFP specific nanobody and the nanobody-antigens-complex. The yellow circle represents the binding reaction. The arrow points toward the nanobody-antigens-complex indicate that the complex is the product of the forward reaction. The double arrows above the yellow circle “binding” indicate that the reaction is reversible.
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Figure 2. Interaction between antigens (GFP) and GFP specific nanobody to form the nanobody-antigen complex
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Result and discussion of the simulation
Another observation is that, as the concentration of the antigen increases, the rate of the reaction (i.e. formation of the nanobody-antigen complex) reaches equilibrium faster (Figure 3.5 to Figure 3.9). This can be explained by the increased forward reaction rate which depends on the concentration of the GFP specific nanobody and antigen (GFP).
Reference
We are a diverse team of CityU undergraduates, working hard to create a better world.
Department of Biology and Chemistry,
Email: cityu.igem2015@gmail.com
ABOUT US
LOCATION
City University of Hong Kong
Tat Chee Avenue, Kowloon,
Hong Kong SAR
CONTACT US
Tel: +852 34427654